Heise Philipp, Liu Yang, Degenkolb Thomas, Vogel Heiko, Schäberle Till F, Vilcinskas Andreas
Department of Bioresources, Fraunhofer Institute for Molecular Biology and Applied Ecology, Giessen, Germany.
Institute for Insect Biotechnology, Justus Liebig University Giessen, Giessen, Germany.
Front Microbiol. 2019 May 31;10:1178. doi: 10.3389/fmicb.2019.01178. eCollection 2019.
The increasing prevalence of antibiotic-resistant human pathogens is a growing public concern and there is intense pressure to identify new antibacterial compounds that can be developed into antibiotics with novel mode of action. Evolutionary theory predicts that insects that have evolved to occupy sophisticated ecological niches by feeding and reproducing on carcasses will depend on their gut microbiome to prevent colonization by invading pathogens taken up with the diet. This inspired our hypothesis that the complex interactions between the core microbiome and the more flexible microbial communities dependent on the environment may promote the outsourcing of antibiotic synthesis to beneficial microbes. We tested this hypothesis by cultivating and characterizing bacteria isolated from the gut of the burying beetle , which feeds and reproduces on small vertebrate carcasses buried in the soil to avoid competitors such as fly maggots. The extracts of isolated bacteria were screened for activity against human pathogens such as , , , and . More than 400 strains were isolated, among which the crude extract of 2MH3-2 displayed promising activity against . Bioactivity-guided fractionation enabled purification of the primary antimicrobial compound of the extract. By LC-MS and NMR experiments, it was identified as serrawettin W2 (CHNO), the antibacterial and nematostatic activity of which was corroborated in our study. We postulate that this antibiotic could contribute to the control of both bacteria and phoretic nematodes in the gut, which compete for food when transferred to the carcass. Our study shows that the gut microbiome of is a promising resource for the screening of antibiotic-producing bacteria.
抗生素耐药性人类病原体的日益流行引发了越来越多的公众关注,因此人们面临着巨大压力,需要识别新的抗菌化合物,这些化合物可被开发成具有新型作用模式的抗生素。进化理论预测,通过在尸体上觅食和繁殖而进化到占据复杂生态位的昆虫,将依赖其肠道微生物群来防止因饮食摄入的入侵病原体的定植。这激发了我们的假设,即核心微生物群与依赖环境的更灵活微生物群落之间的复杂相互作用,可能会促进将抗生素合成外包给有益微生物。我们通过培养和表征从埋葬甲虫肠道中分离出的细菌来检验这一假设,埋葬甲虫在埋于土壤中的小型脊椎动物尸体上觅食和繁殖,以避开诸如蝇蛆等竞争者。对分离出的细菌提取物进行了针对人类病原体如[具体病原体1]、[具体病原体2]、[具体病原体3]和[具体病原体4]的活性筛选。分离出了400多个菌株,其中2MH3-2的粗提物对[目标病原体]显示出有前景的活性。生物活性导向分级分离能够纯化提取物的主要抗菌化合物。通过液相色谱-质谱联用(LC-MS)和核磁共振(NMR)实验,将其鉴定为serratetin W2(C[具体碳数]H[具体氢数]N[具体氮数]O[具体氧数]),我们的研究证实了其抗菌和对线虫的抑制活性。我们推测这种抗生素可能有助于控制肠道中的细菌和携带的线虫,它们在转移到尸体上时会争夺食物。我们的研究表明,埋葬甲虫的肠道微生物群是筛选产抗生素细菌的一个有前景的资源。
